FR2950419A1 - Heat treatment method for heat treatment system i.e. solar cooling system, involves varying speed of desiccant wheel, where speed of desiccant wheel is function of humidity and temperature of air to be dehumidified in inlet of wheel - Google Patents

Abstract

The method involves varying speed of a desiccant wheel, where the speed of the desiccant wheel is a function of humidity and temperature of air to be dehumidified in an inlet of the desiccant wheel, and temperature of re-circulation air for regeneration of desiccant wheel in the inlet of the desiccant wheel. The speed of the desiccant wheel is regulated around an optimal speed. The optimal speed of the desiccant wheel is calculated with a predetermined temporal regulation process according to measurement of operating parameters of the desiccant wheel. An independent claim is also included for a heat treatment system comprising a desiccant wheel.

Description

The invention relates to a heat treatment method using a desiccant wheel and a heat treatment system implementing such a method. In particular, the invention is intended for a cooling system.

FIG. 1 illustrates a solar cooling system by desiccation according to the state of the art, such as for example described in the document US4594860. In such a system, the outside air enters a desiccant wheel 1 after passing through a fan 2. The desiccant wheel has the function of dehumidifying the incoming air by adsorption during its passage. This results in dry and hot air which is then pre-cooled in a sensitive exchanger 3 and then cooled during its passage through a heat exchanger 4, of direct contact humidifier type, to reach the temperature level and / or of humidity, before finally entering the building 5. In parallel, the air leaving the building, under the effect of a fan 7, is cooled by direct contact humidification 6 so as to increase its potential for cooling the treated air, as it passes through the exchanger 3. Then, the outgoing air is heated via a fluid air heat exchanger 8 using the heat supplied by a generator 9, for example from solar type. The hot air obtained, called "recovery" air, then passes through the desiccant wheel 1 so as to regenerate the adsorbent it contains, before being discharged to the outside. This regeneration of desiccant desiccant wheel materials requires a hot source temperature of the order of 45 to 95 ° C. The desiccant wheel 1 is a central organ of such a thermal system because, by dehumidifying the air by adsorption, it determines the amount of cold that can be produced during direct contact humidification. However, its use is not optimized in existing systems. There is a need to improve the performance of such a desiccant heat system.

Thus, a general object of the invention is to provide an optimized solution for the operation of a desiccant wheel thermal system.

For this purpose, the invention is based on a heat treatment process comprising the use of a desiccant wheel, characterized in that it comprises a step of varying the speed (Vrot) of the desiccant wheel.

The speed (Vrot) of the desiccant wheel can be a function of the humidity (Wads) and the temperature (Tads) of the air to be dehumidified at the inlet of the desiccant wheel, and of the air temperature (Tfeg ) regeneration recovery of the desiccant wheel at the inlet of the desiccant wheel. The heat treatment process may comprise a regulation of the speed (Vrot) of the desiccant wheel around an optimum speed (Vrot_opt) obeying the following law: F4-F14 Wads F134 Wads Treg Vrot_opt = F24 Tads F34 Treg - F124 Wads Tads - F234 Tad Treg - F1234 Wads Tads Treg 2 F44 where the nine values (F4 to F44) of this equation are characteristic constants of the operation of the desiccant wheel.

The heat treatment process may comprise a step of calculating the optimum speed (Vrot_opt) of the desiccant wheel with a predetermined regulation time step, as a function of the measurements of the operating parameters (Wads, Tads, Treg) of the desiccant wheel. at each time step, and including transmitting a command to a variable speed motor of the desiccant wheel to obtain the calculated optimum speed.

The heat treatment process may comprise an experimental identification step of the nine constants (F4 to F44) from a minimum of nine measurements of the physical parameters (Wadsx, Tadsx, Tregx, Vrotx) of the desiccant wheel. The at least nine measurements of the physical parameters (Wadsx, Tadsx, Tregx, Vrotx) of the desiccant wheel can be obtained either on a ventilation test bench, or directly in situ on the heat treatment plant, by a procedure of self-learning of a regulator.

The values of the nine constants (F4 to F44) of the desiccant wheel can be obtained from the measurements of the physical parameters (Wadsx, Tadsx, Tregx, Vrotx) and by the resolution of the system of following equations, for x varying from 1 to 9:

F4 + F14 Wadsx + F24 Tadsx + F34 Tregx + F124 Wadsx Tadsx + F134 Wadsx Tregx + F234 Tadsx Tregx + F1234 Wadsx Tadsx Tregx + 2 F44 Vrotx = 0

The invention also relates to a heat treatment system comprising a desiccant wheel, characterized in that it comprises a variable speed motor for the variable speed drive of the desiccant wheel.

The heat treatment system may comprise a regulator implementing the thermal treatment method as described above, and three probes for measuring respectively the humidity (Wads) and the temperature (Tads) of the air to be dehumidified as input desiccant wheel, and the return air temperature (Treg) for the regeneration of the desiccant wheel at the inlet of the desiccant wheel. The heat treatment system can be a solar cooling system.

These objects, features and advantages of the present invention will be set forth in detail in the following description of a particular embodiment made in a non-limiting manner in relation to the appended figures among which:

Figure 1 shows schematically a desiccant wheel cooling system according to the state of the art.

FIG. 2 represents the operation of a desiccant wheel in a thermal system according to one embodiment of the invention.

Figure 3 shows the influence of various factors on the performance of a desiccant wheel of a thermal system. Figure 4 schematically illustrates a desiccant wheel according to an embodiment of the invention in the operation of a cooling system.

The concept of the invention consists in providing a desiccant wheel thermal system in which the desiccant wheel operates at variable speed. Such a system makes it possible to optimize the speed of the desiccant wheel to obtain improved operation of the entire thermal system as a function of the environment. The invention will be illustrated in the context of a cooling system comprising a desiccant wheel 11, illustrated in Figure 2, rotatably mounted within a housing 21, whose rotation is provided by a motor at a speed variable 17 via a belt 16. Each section of the wheel passes through its rotation from an adsorption state to a state of regeneration.

According to the invention, it has been demonstrated that the performance of the desiccant wheel 11 depends on various factors, illustrated in FIG.

The first factor corresponds to the air humidity Wads at the input of the wheel, the second factor corresponds to the air temperature Tads at the input of the wheel and the third factor corresponds to the air temperature Treg of recovery at the inlet of the desiccant wheel. Finally, the fourth factor corresponds to the rotational speed Vrot of the desiccant wheel 11. Next, the performance of the desiccant wheel also depends on other factors corresponding to different combinations of the four preceding main factors. Figure 3 shows the ordinate importance of the factors mentioned above and arranged on the abscissa, the dehumidification performance of the wheel.

Since the first three main factors mentioned above are independent of the system and not directly controllable, since they depend on external conditions, the invention is based on the control of the speed of the desiccant wheel 11 in order to optimize the performance of the system. thermal. This speed of the wheel will preferably be a function of the other influential parameters of the system, ie the air humidity Wads and the air temperature Tads at the input of the wheel, and the temperature of the wheel. Tfey air intake at the inlet of the desiccant wheel. Alternatively, this speed of the wheel could be determined by any other approach, empirical and / or theoretical.

FIG. 4 thus illustrates a cooling system including a desiccant wheel 11 according to an embodiment of the invention. The air coming from the outside arrives via an inlet 12, passes through the desiccant wheel 11 and then exits through an outlet 13 before reaching the other components of the thermal system, similar to those explained in connection with FIG. 1. In parallel , heated air from the interior of the building arrives in opposite direction through an inlet 14 in the desiccant wheel 11 and out of an outlet 15 to the atmosphere. This air called "recovery" has the function of regenerating the desiccant wheel 11, as has been recalled previously. The desiccant wheel is rotated by a motor 17 via a belt 16. The outside air entering the desiccant wheel passes through a first sensor 18 for measuring humidity Wads and a second sensor 19 for measuring temperature Tads.

In addition, another temperature measurement sensor Tfeg 20 is positioned on the input 14 of recovery. The various measurements obtained by these three sensors 18, 19, 20 are transmitted to a regulator 10, which determines the speed of rotation of the wheel by acting on the variable speed motor 17. The invention also relates to an optimization method of a thermal system as described above, comprising the essential step of optimizing the variable speed of rotation of the desiccant wheel. According to the embodiment of the invention, various factors influencing the performance of the desiccant wheel have been identified and it is possible to characterize the performance of the desiccant wheel by the following mathematical formula: dW = Fo + F1 Wads + F2 Tads + F3 Treg + F4 Vrot + F12 Wads Tads + F13 Treg Wads + F14 Vrot Wads + F23 Treg Tad + F24 Vrot Tads + F34 Treg Vrot + F123 Tad Wads Treg + F124 Vrot Tads Tads + F134 Treg Vrot Waves + F234 Tads Vrot Treg + F1234 Wads Tads Treg Vrot + F11 Wads2 + F22 Tads2 + F33 Treg 2 + F44 Vrot 2

where dW represents the variation in dehumidification performance of the desiccant wheel, where Wads, Tads, Treg, and Vrot are the previously defined wheel performance influence factors and where the Fo to F44 constants are characteristic of the operation. desiccant wheel.

The values of these different characteristic constants of a desiccant wheel can for example be determined using the recursive least squares method.

Then, we obtain the optimization of the system performance according to the speed of the wheel from the following equation: dW dVrot = 0 The resolution of this equation makes it possible to determine the optimal value Vrot_opt of the speed of rotation of the wheel. the desiccant wheel according to the temperature and humidity of the air entering the desiccant wheel: - F4- F14 Wads - F24 Tads - F34 Treg - F124 Wads Tads - F134 Wads Treg - F234 Tregs Treg - F1234 Wads Tads Treg 2 F44 So it therefore appears that this optimal speed Vrot_opt depends on 9 constants to be identified. Alternatively, the above equations could be simplified, for example by choosing, for example, to omit the least influential parameters. For example, parameters whose impact (Figure 3) is less than 10% of the impact of the most influential parameter can be considered negligible.

Then, the optimization process of the thermal system comprises a preliminary step of experimental identification of the nine constants, starting from a minimum of nine different measurements of the physical parameters Wadsx, Tadsx, Tregx, and Vrotx of the system.

Determining the constants of the system ultimately consists of solving the following system of equations, for x ranging from 1 to 9: F4 + F14 Wadsx + F24 Tadsx + F34 Tregx + F124 Wadsx Tadsx + F134 Wadsx Tregx + F234 Tadsx Tregx + F1234 Wadsx Tadsx Tregx + 2 F44 Vrotx = 0

Variations in the operation of the system can be obtained either on a ventilation test bench by the manufacturer, or directly in situ on the installation, by a self-learning procedure of the regulator 10. In the latter case, the different The measurements obtained by the three sensors 18, 19, and 20 shown in FIG. 4 make it possible to identify the nine measurement points necessary for identifying the constants of the system. Advantageously, these measurements can be obtained over several hours of operation of the desiccant wheel in order to obtain sufficient climatic variations to obtain sufficiently distant entry points (Wadsx, Tadsx, Tregx, Vrotx). Thus, it is possible to define an acquisition step, an acquisition time and minimum and maximum rotational speeds of the desiccant wheel during this acquisition period during which the regulator 10 records the measurements of the physical parameters (Wadsx , Tadsx, Tregx, Vrotx) of the system. When these different measurements are obtained, the regulator solves the nine-equation system presented above and obtains at the output the nine constants sought.

Then, the regulator 10 uses these values to determine the optimal rotation speed of the thermal system, as given by formula (i) above. For this purpose, it can operate with a predetermined regulation time step, for example defined by the user. At each regulation time step, it calculates the optimum speed of the desiccant wheel according to the measurements obtained by the three sensors 18, 19, 20 and transmits the corresponding command to the variable speed motor 17.

Finally, the thermal system according to the proposed solution has the following advantages: it makes it possible to increase the performances of the system without profound modification of the architecture of the system, since it suffices to replace the initial motor by a variable speed motor, to add two temperature probes and a humidity probe, and to add a speed regulator which controls the engine optimally by implementing the method described above. The controller can consist of any hardware and / or software device, such as any computer, a microprocessor ... - there is an increase in dehumidification performance of the desiccant wheel of up to 24%; it is also necessary to underline the reduction of the electrical consumption of the motor of the desiccant wheel, which also makes it possible to increase the electrical efficiency of the system.

Naturally, the invention has been illustrated in the context of a solar cooling system but it can very well be implemented more generally on any thermal system comprising a desiccant wheel. On the other hand, precise control of the speed of the desiccant wheel has been proposed as an advantageous example. Any other regulation of the speed of the desiccant wheel of such a thermal system can be imagined without departing from the scope of the invention.

Claims (10)

Revendications1. A heat treatment process comprising the use of a desiccant wheel (11), characterized in that it comprises a step of varying the speed (Vrot) of the desiccant wheel. 2. Heat treatment process according to the preceding claim, characterized in that the speed (Vrot) of the desiccant wheel is a function of the humidity (Wads) and the temperature (rads) of the air to be dehumidified as input desiccant wheel, and air temperature (Tfeg) recovery regeneration of the desiccant wheel at the inlet of the desiccant wheel. 3. Heat treatment process according to the preceding claim, characterized in that it comprises a regulation of the speed (Vrot) of the desiccant wheel around an optimal speed (Vrot_opt) obeying the following law: (F4- F14 Wads - F24 Tads - F34 Treg - F124 Tad Wads - F134 Treg Wads - F234 Treg Tads - F1234 Tad Wads Treg rot_opt - 20 where the nine values (F4 to F44) of this equation are characteristic constants of the operation of the desiccant wheel. 4. Heat treatment process according to the preceding claim, characterized in that it comprises a step of calculating the optimum speed (Vrot_opt) of the desiccant wheel with a predetermined regulation time step, as a function of the measurements of the operating parameters. (Wads, Tads, Treg) of the desiccant wheel at each time step, and in that it comprises a transmission of a control to a variable speed motor of the desiccant wheel in order to obtain the calculated optimum speed. 5. Heat treatment process according to claim 3 or 4, characterized in that it comprises a step of experimental identification of the nine constants (F4 to F44) from a minimum of nine measurements of the physical parameters (Wadsx, Tadsx). , Tregx, Vrotx) of the desiccant wheel. 6. Heat treatment process according to the preceding claim, characterized in that the at least nine measurements of the physical parameters (Wadsx, Tadsx, Tregx, Vrotx) of the desiccant wheel are obtained either on a ventilation test bench, or directly in located on the heat treatment plant, by a self-learning procedure of a regulator (10). 7. Heat treatment process according to one of claims 5 or 6, characterized in that the values of the nine constants (F4 to F44) of the desiccant wheel are obtained from the measurements of the physical parameters (Wadsx, Tadsx, Tregx, Vrotx) and by solving the following system of equations, for x ranging from 1 to 9: F4 + F14 Wadsx + F24 Tadsx + F34 Tregx + F124 Wadsx Tadsx + F134 Wadsx Tregx + F234 Tadsx Tregx + F1234 Wadsx Tadsx Tregx + 2 F44 Vrotx = 0 8. Heat treatment system comprising a desiccant wheel (11), characterized in that it comprises a variable speed motor (17) for the variable speed drive of the desiccant wheel. 9. heat treatment system according to the preceding claim, characterized in that it comprises a regulator (10) implementing the heat treatment method according to one of Claims 1 to 7, and three probes (18, 19, 20). for measuring respectively the humidity (Wads) and the temperature (Tads) of the air to be dehumidified at the inlet of the desiccant wheel, and the return air temperature (Treg) for the regeneration of the desiccant wheel at the entrance of the desiccant wheel. 10. Heat treatment system according to claim 8 or 9, characterized in that it is a solar cooling system.